Difference between revisions of "Team:Technion Israel/Color"

Line 372: Line 372:
 
<div class="col-md-6 col-sm-12 vcenter"><!--6 text-->
 
<div class="col-md-6 col-sm-12 vcenter"><!--6 text-->
 
<p class="text-justify">
 
<p class="text-justify">
<a href="https://2016.igem.org/Team:Technion_Israel/Design">FlashLab</a> system is based on the idea of moving bacteria expressing
+
<a href="https://2016.igem.org/Team:Technion_Israel/Design">FlashLab</a> system is based on a two-plasmid system, where motile  bacteria express both
 
chromoproteins using two different expression plasmids. In order to verify the idea Tar was chosen as the chemoreceptor and amilCP as the chromoprotein. The first  
 
chromoproteins using two different expression plasmids. In order to verify the idea Tar was chosen as the chemoreceptor and amilCP as the chromoprotein. The first  
plasmid (<a href="http://parts.igem.org/Part:BBa_K1992004" target="_blank">K1992004</a>) causes the expression of Tar chemoreceptor.  
+
plasmid (<a href="http://parts.igem.org/Part:BBa_K1992004" target="_blank">K1992004</a>) expresses the Tar chemoreceptor.  
The plasmid contains chloramphenicol (CM) resistance. The second  
+
Talong with chloramphenicol (CM) resistance. The second  
plasmid causes the expression of chromoprotein (see Implementation –  
+
plasmid expresses a chromoprotein (see Implementation –  
part haven’t been submitted). The plasmid contains ampicillin (Amp)  
+
part haven’t been submitted)along with ampicillin (Amp)  
resistance. The two plasmids were co-transformed to UU1250 strain. The strain
+
resistance. Follolwing transformation of the two plasmids into UU1250 strain, the colonies were selected by plating on LB agar plates with two antibiotic. The plating results  
was then screened by using two antibiotic LB agar plates. The plating results  
+
showed colored colonies and non-colored ones (Fig 2), that is due to the  
showed colored colonies and non-colored ones (Fig 2), that due to the  
+
 
non-compatible ORI of the two plasmids (see Outlook section).  
 
non-compatible ORI of the two plasmids (see Outlook section).  
 
</p>
 
</p>
Line 388: Line 387:
 
<img src="https://static.igem.org/mediawiki/2016/a/ac/T--Technion_Israel--colornew1.jpg" class="img-responsive img-center img-cont" width="450" style="cursor: pointer;">
 
<img src="https://static.igem.org/mediawiki/2016/a/ac/T--Technion_Israel--colornew1.jpg" class="img-responsive img-center img-cont" width="450" style="cursor: pointer;">
 
</a>
 
</a>
<p class="text-center"><b>Fig. 2:</b> Co-transformtion of <a href="http://parts.igem.org/Part:BBa_K1992004" target="_blank">K1992004</a> and tsPurple expressing plasmid to UU1250 strain.</p>
+
<p class="text-center"><b>Fig. 2:</b> Co-transformation of <a href="http://parts.igem.org/Part:BBa_K1992004" target="_blank">K1992004</a> and tsPurple expressing plasmid to UU1250 strain.</p>
 
</div>
 
</div>
 
</div>
 
</div>
Line 423: Line 422:
 
<a href="https://2016.igem.org/Team:Technion_Israel/Experiments">swarming assay</a> (Fig 4). A halo was formed after  
 
<a href="https://2016.igem.org/Team:Technion_Israel/Experiments">swarming assay</a> (Fig 4). A halo was formed after  
 
8 hours indicating functional chemotaxis response. For our  
 
8 hours indicating functional chemotaxis response. For our  
<a href="https://2016.igem.org/Team:Technion_Israel/Experiments">chip assay</a> more instance color is needed, in order to obtain
+
<a href="https://2016.igem.org/Team:Technion_Israel/Experiments">chip assay</a> more intense color was needed. Thus, the sample was centrifuge and resuspended in a smaller volume  
that the sample was centrifuge and resuspend in a smaller volume  
+
 
of TB medium, increasing the bacterial concentration by 10 folds.  
 
of TB medium, increasing the bacterial concentration by 10 folds.  
 
Results can be seen in the <a href="https://2016.igem.org/Team:Technion_Israel/Proof">Proof of concept page</a>.
 
Results can be seen in the <a href="https://2016.igem.org/Team:Technion_Israel/Proof">Proof of concept page</a>.
Line 440: Line 438:
 
Swarming assay results (left to right) - UU1250 expressing only Tar chemoreceptor;  
 
Swarming assay results (left to right) - UU1250 expressing only Tar chemoreceptor;  
 
UU1250 expressing Tar chemoreceptor and tsPurple chromoprotein;  
 
UU1250 expressing Tar chemoreceptor and tsPurple chromoprotein;  
UU1250 only; &Delta;Z - <i>E.coli</i> expressing all chemoreceptors.
+
UU1250 only; &Delta;Zras - <i>E.coli</i> expressing all chemoreceptors.
 
</p>
 
</p>
 
</div>
 
</div>
Line 472: Line 470:
 
<div class="col-md-12 col-sm-12">
 
<div class="col-md-12 col-sm-12">
 
<p class="text-justify">
 
<p class="text-justify">
We succeeded to get colored bacteria grown in the optimal condition for our assay.  
+
We succeeded to get colored bacteria grown in the optimal condition of our assay.  
At that point both, the chemoproteins and the receptors, cloned on high copy  
+
Though both the chemoproteins and the receptors were cloned on high copy  
 
plasmid with the same ORI - pMB1 (pSB1C3 and pSB1A2). Usually, plasmids with the  
 
plasmid with the same ORI - pMB1 (pSB1C3 and pSB1A2). Usually, plasmids with the  
 
same ORIs are incompatible because they will compete for the same machinery,  
 
same ORIs are incompatible because they will compete for the same machinery,  
creating an unstable and unpredictable environment. For future plan we mean to  
+
creating an unstable and unpredictable environment. For future plan we suggest to  
clone one of the expression systems to plasmid containing different ORI,  
+
clone one of the expression systems to a plasmid containing different ORI,  
 
compatible to pMB1 ORI. This adjustment will improve the stability of our  
 
compatible to pMB1 ORI. This adjustment will improve the stability of our  
 
system and allow better control over the expression of each protein.
 
system and allow better control over the expression of each protein.

Revision as of 21:09, 19 October 2016

S.tar, by iGEM Technion 2016

S.tar, by iGEM Technion 2016

Introduction


Chromogenic proteins usually serve as a useful reporter in determining gene expression levels without the need of a fluorescent microscope. However, the FlashLab technology implements these chromogenic proteins for a different purpose. Due to the chips structure, when the bacteria moves towards or away from substance, a cluster is formed and the presence of chromogenic proteins allows the user to spot it in the naked eye without the need for a complex device (for more information about our chip click here).

Implementation


Three chromogenic proteins (chromoproteins) were tested for the S.Tar system, all which were provided and extracted from the iGEM 2016 kit. Each part contained RBS, chromoproteins coding sequence and a double terminator. The different parts contained the following proteins:
- tsPurple, visible as purple color (K1357008).
- amilCP, visible as blue color (K1357009).
- mRFP, visible as red color and can serve also as red fluorescence protein (K1357010).

To test the expression and visibility of those proteins, a strong promoter (J23100) was cloned upstream to the RBS using the RFC10 assembly (Fig 1).

Fig. 1: High expression system of chromogenic protein.

This plasmid is one of two plasmids constructing our FlashLab system, as the other is plasmid expressing a chemoreceptor. The two plasmids are co-transformed to UU1250 strain expressing both, the designed receptor and a chosen color. Each plasmid contains different antibiotic resistance allowing easy screening for strain expressing both proteins.

Results


The first step, as mentioned in the implementation section, was to clone a strong promoter (J23100) upstream to each part, creating a high expression system. The biological system was then transformed to E.coli Top10 strain and UU1250 strain. Plating results showed colored colonies, for both strains, as expected. Colored colony from each type was incubated overnight at 37℃ in LB medium. Overnight incubation resulted in a medium that appeared as colored, due to high concentration of bacteria expressing chromoproteins. The results of centrifuging the medium sample was a colored pellet (Fig 1).

Fig. 1: E.coli Top10 strain expressing (left to right): mRFP, tsPurple, amilCP.

As both strain showed similar results the following experiments conducted only with the UU1250 strain, the strain which was used for chemotaxis assays. Growth conditions for chemotaxis assays require a minimal growth medium, TB, and a temperature of 30℃(1).
Overnight growing, in this condition, of UU1250 strain expressing chromoproteins resulted in a colorless medium, although bacterial concentration was high. In order to overcome this issue, two different growth conditions were tested. Incubation at 37℃ in TB medium and incubation at 30℃ in LB medium. At 37℃ TB medium, color was detected. The color was less intense compared to the 37℃ LB medium, but still high enough to be detected by a naked eye. Moreover the pellet's color intensity was similar to the one grown 37℃ LB pellet. As for the 30℃ LB medium no color was detected after overnight growth. In addition, the pellet was also colorless.
These results imply that the growth temperature has a significant influence on the chromoprotein expression. To achieve color intensity at the right conditions a two-stage growth was conducted. The first stage is incubation at 37℃ LB medium in order to gain a high expression of chromoproteins. The culture is then centrifuge and resuspend with TB medium. The second stage is incubation at 30℃ for 3 hours, for restoring chemotaxis abilities. This two-stage growth allows both color expression and chemotaxis ability to the bacteria and was proven to be effective in matter for chromoprotein expression, as for chemotaxis ability test, the two palsmid system was conducted.

The two plasmid system

FlashLab system is based on a two-plasmid system, where motile bacteria express both chromoproteins using two different expression plasmids. In order to verify the idea Tar was chosen as the chemoreceptor and amilCP as the chromoprotein. The first plasmid (K1992004) expresses the Tar chemoreceptor. Talong with chloramphenicol (CM) resistance. The second plasmid expresses a chromoprotein (see Implementation – part haven’t been submitted)along with ampicillin (Amp) resistance. Follolwing transformation of the two plasmids into UU1250 strain, the colonies were selected by plating on LB agar plates with two antibiotic. The plating results showed colored colonies and non-colored ones (Fig 2), that is due to the non-compatible ORI of the two plasmids (see Outlook section).

Fig. 2: Co-transformation of K1992004 and tsPurple expressing plasmid to UU1250 strain.

The colored colonies were isolated and grown using the two-stage growth method mentioned previously. The result is high density and colored medium (Fig 3).

Fig. 3: Left tube - UU1250 strain expressing Tar chemoreceptor only (K1992004). Right tube - UU1250 strain expressing Tar chemoreceptor and tsPurple chromoprotein.

The sample was then tested for chemotaxis ability using swarming assay (Fig 4). A halo was formed after 8 hours indicating functional chemotaxis response. For our chip assay more intense color was needed. Thus, the sample was centrifuge and resuspended in a smaller volume of TB medium, increasing the bacterial concentration by 10 folds. Results can be seen in the Proof of concept page.

Fig. 4: Swarming assay results (left to right) - UU1250 expressing only Tar chemoreceptor; UU1250 expressing Tar chemoreceptor and tsPurple chromoprotein; UU1250 only; ΔZras - E.coli expressing all chemoreceptors.

Outlook


We succeeded to get colored bacteria grown in the optimal condition of our assay. Though both the chemoproteins and the receptors were cloned on high copy plasmid with the same ORI - pMB1 (pSB1C3 and pSB1A2). Usually, plasmids with the same ORIs are incompatible because they will compete for the same machinery, creating an unstable and unpredictable environment. For future plan we suggest to clone one of the expression systems to a plasmid containing different ORI, compatible to pMB1 ORI. This adjustment will improve the stability of our system and allow better control over the expression of each protein.

References:
1. MAEDA, Kayo, et al. Effect of temperature on motility and chemotaxis of Escherichia coli. Journal of bacteriology, 1976, 127.3: 1039-1046.‏




S.tar, by iGEM Technion 2016